WO2008138167A1

WO2008138167A1 - A method for producing coal gas

Info

Publication number: WO2008138167A1
Application number: PCT/CN2007/001547
Authority: WO
Inventors: Zhiping Xie
Original assignee: Foshan Keda Energy Resource Machinery Co., Ltd.
Priority date: 2007-05-14
Filing date: 2007-05-14
Publication date: 2008-11-20
Also published as: US8029581B2; EP2149595A4; US20100058664A1; EP2149595B1; AU2007353260A1; AU2007353260B2; EP2149595A1

Abstract

A method for producing coal gas comprises: introducing raw coal powders (1) and high temperature gasification agents (7) into a gasification furnace (a) for reacting and producing coal gas, the produced coal gas leaving the furnace and exchanging heat with gasification agents and producing high temperature gasification agents (7), the coal gas exchanging heat with water and producing steam (4) which is one part of the gasification agents, dusting, desulfurizing and outputting the coal gas. The coal gas is dry type high temperature separated before exchanging heat with the gasification agents, and coal powders (2) separated from the coal gas are returned to the gasification furnace (a). The coal gas is dry type low temperature separated after producing high temperature gasification agents (7) and before producing steam (4) by heat exchanging with water, and coal powders (5) separated from gas stream are returned to the gasifier furnace (a). The high temperature gasification agents (7) have a temperature of 750-850 °C and are conveyed to the furnace (a) from three locations. The method has a low consumption of coal, low equipment attrition, a high heat value of produced coal gas.

Description

Gas production method

The present invention relates to a method of producing coal gas, and more particularly to a method of producing coal gas from pulverized coal. Background technique

The process of producing coal gas using pulverized coal generally includes feeding pulverized coal, steam, air and oxygen into a gas generating furnace to cause a reaction at a high temperature to generate gas, and the generated gas is returned to the pulverized coal through a cyclone. In the gas generator, the gas is used to generate steam through the waste heat boiler, and the cleaned and cooled gas is sent to the user. Since the temperature of the gas coming out of the gas generator is very high, the steam generated after the waste heat boiler exceeds the gas production requirements, and the excess is used for other purposes; and because of the steam, air and oxygen entering the gas furnace. The temperature of the gasifying agent is relatively low, usually 65 °C ~ 12 (TC, and the temperature of the gasifying agent needs to rise to 100 (TC ~ 1100 °C) during the reaction in the furnace, which is consumed during the temperature increase of the gasifying agent. A large amount of heat of reaction. The above factors all cause a relatively high coal consumption per unit of gas produced, usually at 0.3 Kg/Nm ³ ~ 0.4 Kg/Nm ³ or more; and the gas produced by the above conventional process has a low calorific value.

In order to solve the above problems, an object of the present invention is to provide a gas production method which not only reduces coal consumption but also increases the heat value of the generated gas.

In order to achieve the above object, the present invention provides a gas production method comprising: adding a raw material pulverized coal and a high-temperature gasifying agent to a gas generating furnace to generate a gas;

The hot gas is exchanged with the gasifying agent to generate a high temperature gasifying agent;

The gas after heat exchange with the gasifying agent exchanges heat with water to produce steam, which is a component of the gasifying agent;

The gas after heat exchange with water is further dedusted and desulfurized and then output. After the gas is generated and before the heat exchange with the gasifying agent, it is subjected to a thousand-type high-temperature separation treatment, and the separated pulverized coal is sent back to the gas generator. After the high-temperature gasification agent is produced, the gas is exchanged with the water to produce steam, and the dry coal is subjected to dry low-temperature separation treatment, and the separated pulverized coal is sent back to the gas generator.

The temperature of the heat exchange between the tapping gas and the gasifying agent is 50 (TC - 700 'C; the heat exchange between the gas and the water is carried out in a waste heat boiler, and the inlet temperature of the waste heat boiler is 400 ° C - 500. C.

The gasifying agent is air and steam, oxygen-enriched air and steam, or pure oxygen and steam.

When initially operated, the raw coal powder is added from the lower portion of the gas generator. When the temperature of the gas generator is operating normally, the raw coal powder is fed from the upper portion of the gas generator.

The high temperature gasifying agent is fed from three locations of the gas generator; the first of the three positions is located at a lower portion of the gas generator, and the high temperature gasifying agent is fed in a amount of 50% - 60%; the second is located in the middle of the gas generator, the high-temperature gasifying agent is fed in an amount of 35% - 45%; the third is located in the middle of the gas generating furnace; The pulverized coal separated by the cryogenic separator is sent to a gas generator together, and the high-temperature gasifying agent is fed in an amount of 5%.

The high temperature gasifying agent has a temperature of from 750 ° C to 850 ° C.

The coal gas supplied to the user has a pulverized coal content of 5 mg/Nm ³ . The proportion of air, oxygen-enriched air or pure oxygen in the gasifying agent is: 50 - 80 %, and the proportion of steam in the gasifying agent is 20 - 50%.

The gas production method provided by the invention exchanges the gasification agent entering the furnace with the gas discharged from the furnace, so that the temperature of the gasification agent entering the furnace reaches 750 ° C ~ 850 ° C, so the reaction of the pulverized coal with the high temperature gasification agent The calorie consumption is 20% to 30% lower than that of the normal temperature gasifying agent, and the combustible component of the gas is 20% to 30% higher than the mixed gas of the normal temperature gasifying agent. Specifically, the present invention heats the gas from 950 ° C to 1100 ° C of the gas furnace and 60 ° C ~ 10 (the gasification agent of TC exchanges heat through the heat exchanger, and the temperature of the gasification agent after heat exchange rises to 750 ° C - 850 ° C, the temperature drops to 40 (TC ~ 500 °C gas and then enter the waste heat boiler to produce steam, after the waste heat boiler comes out, the gas temperature drops to about 150 °C, into the Venturi dust collector and washing tower dust removal, After the final desulfurization, it is sent to the user. Through the heat exchange between the gas and the gasifying agent, the gas heat is supplied to the gasifying agent, and the temperature of the gasifying agent rises, so that the steam content increases, and the reaction speed with the coal increases, not only the coal The gas generator has low coal consumption and good gas composition. More importantly, the heat in the gas is effectively recovered, and the coal consumption is reduced by 20% to 30%. Compared with the coal consumption of the prior art gas furnace using the normal temperature gasifying agent of 0.3 g/Nm ³ to 0.4 Kg/Nm ³ , the coal consumption of the mixed gas of the present invention is reduced to 0.22 g/Nm ³ to 0.25 Kg/Nm ³ ₀ . The invention adopts two separations of high temperature and low temperature to greatly reduce the amount of pulverized coal carried by the gas, and the separated pulverized coal is reintroduced into the furnace, thereby further reducing the coal consumption of the gas generator. The calorific value of the mixed gas produced by the air-steaming gasification agent is 5600 KJ/Nm ³ - 6000 KJ/Nra ³ , (1350 kcal/Nm ³ ~ 1450 kcal/Nm ³ ), and the coal consumption is only 0.22 Kg/Nm ³ ~ 0.25 Kg/Nm ³ , low coal consumption, high calorific value, high production efficiency and low cost.

DRAWINGS

1 is a flow chart 1 of an embodiment of a gas generating method of the present invention. detailed description

The implementation of the present invention will be specifically described below with reference to FIG. 1:

The raw material pulverized coal 1 with water content < 8% is sent to the gas generator through the coal feeder. If the water content of the raw pulverized coal is higher than 8%, it needs to be dried first. At the beginning of operation, the raw pulverized coal 1 is generated from the gas. The lower part of the furnace is fed. When the furnace temperature is normal, the raw material pulverized coal 1 is sent from the upper part of the gas generating furnace; at the same time, the high temperature gasifying agent 7 having a temperature of 750 - 850 ° C is fed into the gas generating furnace from three positions. A reaction occurs in the gas generator to generate gas. One of the three locations is added from the lower portion of the gas generator, the amount of addition is 50% - 60%, and the other is added from the middle of the gas generator. The addition amount is from 35% to 45%, and the third enters from the circulating coal inlet of the gas generator, and the circulating coal is sent to the gas generator, which accounts for 5% of the total high-temperature gasification dose; the gas passes through a dry high temperature The separator separates the pulverized coal 1 carrying the particles having a diameter larger than 10 μm, and is sent back to the gas generator as circulating coal, and then separated into a heat exchanger, and exchanges heat to the air 3 and steam 4 Composed of a gasifying agent, making The chemical is heated to 750 - 850 high temperature gasification agent 7, the temperature of the gas is 500 - 700 ° C, the temperature of the gas out of the heat exchanger is 400 - 500 ° C, and then enters a dry low temperature The separator further separates all of the coal particles larger than 5 μπι, and separates 50% of the 0-5 μη diameter particles, The separated pulverized coal 5 is returned to the gas generating furnace as circulating coal; after the low temperature separator is passed, the gas enters a waste heat boiler for generating steam 4, and the steam 4 is a component of the gasifying agent, and the gas of the waste heat boiler is discharged. Entering a venturi wet scrubber and scrubber for de-treatment and further dedusting, wherein the circulation of the washing liquid 8 in the venturi wet scrubber and the washing tower and the settling device is maintained by a water pump, after the above-mentioned wet dust separation 90% of the particles are less than 5 μηι of pulverized coal, and after sedimentation by the sedimentation equipment, the slag 9 is filtered and discharged, and the gas 6 washed by the washing tower can be delivered to the user. In the above process, the air may also be oxygen-enriched air or pure oxygen; the gas production process reduces the coal consumption by heating the gasification agent into the gas generator after preheating; and the raw material pulverized coal enters the gas generator from two inlets, and The gas-carrying pulverized coal is returned to the gas generator, which further reduces the coal consumption, so that the coal consumption is only 0.22 g/Nm ³ ~ 0.25 Kg/Nm ^{3 of} gas, and the calorific value of the gas is increased to 600 KJ/Nm ³ gas. ~ 6000n/Nm ³ gas (1350 kcal / Nm ³ gas ~ 1450kcal / Nm ³ gas). Specifically, in the present embodiment, the air consumption is 0.6 - 0.65 Kg / Nm ^{3 of} gas. The composition of the gas composition obtained is: H ₂ : 15% - 20%; CO: 25% - 30%; C0 ₂ : 5 % - 8 %; N ₂ : 40% - 50%; (3⁄4: 2% -3 %; 0 ₂ : 0.2% - 0.5%. The ratio of air, oxygen-enriched air or pure oxygen in the gasifying agent is: 75 - 80%, and the proportion of steam is 20 - 25 %. The parameters in this embodiment are as follows: Combination:

Gasification agent preheating heat exchanger outlet gas consumption coal consumption Kg/Nm ³ gas calorific value Π / Nm ³ degrees. C body temperature °C

750 500 0.25 5600

850 400 0.22 6000

800 450 0.24 5800 The calculation of the gas consumption of IKcal by using air and steam as a gasifying agent below further theoretically supports the practice of the present invention.

25 ° C gasification agent +25 ° C coal ► 1050 ° gas + 1050 ° (: steam

850 ° C gasification

85 (TC gasification agent + 950 ° C coal ► 25 ° C gas + 25 ° C steam mixture specific heat: 0.33kcal / Nm ^3o C

ΔΗ! = mixed gas with heat = INm ³ gas mixture volume X 850 ° C χ 0.33

= 0.8066 χ 850 0.33 = 5068kcal/kmol. Gas

Coal consumption = 0.25kg/Nm ³ = 5.6kg/kmol

Specific heat of raw materials = 0.5kal/kg °C

ΔΗ, = cold coal heating heat = coal consumption X raw material specific heat X coal temperature X raw material water evaporation heat

= (0.25-0.25 X 0.1) X 0.5 X (950-25) 22.4 + 0.25 0.1 χ 580 χ 22.4 = 2655.8kcal/kmol

C+0 ₂ ——► C0 ₂ H° _co2 = 97700kcal/kmol

C+0 ₂ /2 ► CO H° _co = 29400kcal/kmol

C+H ₂ 0 ►CO H° _co = -28300kcal/kmol

C0 ₂ content 7%, lkmal gas air 4.55/7.19 = 0.632kcal/kmol gas 0.632kmol air oxygen 0.132kmol, CO oxygen consumption is half of C0 ₂

△ H inverse = heat generated by air C0 ₂ + heat generated by air CO + steam generates heat of C0 ₂ = 0.07 X 97700 + [(0.132-0.07) χ 2 29400] + [0.265-2 χ (0.132-0.07)] χ (-28300) -64694.3kcal/kmol gas

Gas specific heat is 0.33kcal/Nm ³ gas;

lNm3 gas generates 1.04Nm ³ wet gas;

ΔΗ ₃ = 8025.5kcal / kmol Therefore, the production of lkmol gas is heat: Q = ΔΗ ₂ + ΔΗ ₃ + ΔΗ

= 5068 + (-2655.8 ) + 8025.5 + 6494.3

= 881kcal/kmol gas

It can be seen from the calculation that the result is approximately balanced, and the remaining 881 kcal/kmol of gas can be used for multi-generation. Finally, the above embodiments are only used to illustrate the technical solution of the present invention and not limiting, although the present invention is described with reference to the preferred embodiment. The invention has been described in detail, and those skilled in the art will understand that the invention may be modified or equivalently substituted without departing from the spirit and scope of the invention.

Claims

Claim

A gas production method, characterized in that it comprises:

Adding raw material pulverized coal and high-temperature gasifying agent to the gas generator to form a gas;

The gas after heat exchange with water is further dedusted and desulfurized and then output.

The gas producing method according to claim 1, wherein the separated pulverized coal is returned to the gas generating furnace after the gas is generated and subjected to dry high-temperature separation treatment before heat exchange with the gasifying agent.

3. The method for producing a gas according to claim 1, wherein after the high-temperature gasifying agent is produced, the gas and the water are subjected to heat exchange to produce steam, and then subjected to dry low-temperature separation treatment, and the separated pulverized coal is sent. Go back to the gas generator.

The gas production method according to claim 1, wherein the temperature at which the outlet gas and the gasifying agent exchange heat is 500 ° C - 700 ° (.

The gas production method according to claim 1, wherein the gas and water are heat-exchanged in a waste heat boiler, and an inlet temperature of the waste heat boiler is 400 °C - 500 °C.

The gas producing method according to claim 1, wherein the gasifying agent is air and steam, oxygen-enriched air and steam, or pure oxygen and steam.

The gas producing method according to claim 1, wherein the raw coal powder is added from a lower portion of the coal gas generating furnace.

The gas producing method according to claim 1, wherein the raw coal powder is fed from an upper portion of the coal gas generating furnace.

The gas production method according to any one of claims 1 to 8, wherein said high-temperature gasifying agent is fed from three positions of said gas generating furnace; and said first one of said three positions is said In the lower part of the gas generator, the high-temperature gasifying agent is fed in an amount of 50% - 60%; the second is located in the gas generating furnace In the middle portion, the high-temperature gasifying agent is fed in an amount of 35% to 45%; the third portion is located in the middle portion of the gas generating furnace; and the high-temperature gasifying agent is fed in a amount of 5%.

The gas production method according to any one of claims 1 to 8, wherein the high temperature gasifying agent has a temperature of from 750 °C to 850 °C.